Heat cooler

ABSTRACT

Provided is a heat cooler configured to rapidly cool a heat-generating device by transferring heat generated from the heat-generating device to an outside area. The heat cooler includes a heat conductive body having a predetermined volume and sealing members. The body includes a plurality of penetration holes formed through top and bottom surfaces of the body. The sealing members are hermetically coupled to the top and bottom surfaces of the body. The bores are sealed with the sealing members to form independent accommodation portions, and a plurality of heat conductive beads and a refrigerant are filled in the accommodation portions in a state where the refrigerant permeates between the heat conductive beads.

REFERENCE TO RELATED APPLICATIONS

This application claims the priority benefit of Korean Patent Application No. 10-2010-0049375 filed May 26, 2010 and Korean Patent Application No. 10-2010-0056701 filed Jun. 15, 2010, the entire contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to a heat cooler for cooling a heat-generating electronic device, and more particularly, to a heat cooler configured to rapidly cool a heat-generating device by dissipating heat generated from the heat-generating device to an outside area.

BACKGROUND OF THE INVENTION

Heat pipes, heat spreaders, and heat sinks having good heat conduction, dissipation, and diffusion characteristics have been used individually or in combination for rapidly cooling heat-generating devices of electronic apparatuses.

In the electronic industry, capillary coolers such as heat pipes and heat spreaders are used to transfer heat to outside areas by utilizing the capillary phenomenon. For example, a refrigerant such as distilled water is circulated in a vacuum-state heat pipe or heat spreader so as to rapidly dissipate heat generated from a heat-generating device such as a microprocessor.

In a metal heat pipe of the related art, a plurality of grooves are formed in the inner wall of the metal heat pipe, and distilled water is moved in a vacuum state along the grooves so as to cause the distilled water to evaporate for rapidly transferring heat to a low-temperature region. The surface area of the inner wall of the metal heat pipe is varied according to the size and number of the grooves formed in the inner wall of the metal heat pipe, and the heat-transfer ability of the metal heat pipe is determined by the size of the surface area of the inner wall of the metal heat pipe. However, it is difficult to adjust the size and number of the grooves due to structural or manufacturing difficulties.

Moreover, since the grooves are formed only in the inner wall of the metal heat pipe, the inner surface area of the metal heat pipe is not sufficient large for rapidly transferring heat using a medium such as distilled water.

In addition, since the inside of the metal heat pipe is hollow, heat dissipation through the metal heat pipe is not sufficient.

In another kind of metal heat pipe of the related art, a plurality of wicks formed of copper wires by weaving or braiding are disposed in the metal heat pipe, and distilled water is moved in a vacuum state between the copper wires of the wicks by the capillary phenomenon so as to cause the distilled water to evaporate for rapidly transferring heat to a low-temperature region.

In this case, however, it is difficult to insert many copper-wire wicks in the metal heat pipe. Therefore, the inner surface area of the metal heat pipe is also insufficient for rapidly transferring heat using a medium such as distilled water.

As described above, heat pipes of the related art are limited in increasing their inner surface areas. Furthermore, it is difficult to manufacture heat pipes of the related art.

In addition, heat pipes of the related art have low heat conductivity because materials having high heat conductivity are not sufficiently used.

In addition, since the inner space of a heat pipe of the related art is filled with, for example, a refrigerant, a vacuum space, and a wick, the heat conductivity of the heat pipe is not high, and efficient cooling using the properties of latent heat and specific heat cannot be carried out.

Therefore, in the related art, for example, a heat sink having high heat conductivity is used together with a circular-pipe shaped or plate-shaped heat pipe having good heat diffusion characteristics but insufficient heat conductivity.

For example, a heat sink constituted by only a metal body having high heat conductivity is used in the related art.

Such a heat sink is relatively large and has high heat conductivity. The heat sink is attached to a heat-generating device to dissipate heat generated from the heat-generating device to the atmosphere.

Although the heat sink has high heat conductivity, heat diffusion through the heat sink is not satisfactory. Moreover, the heat sink has limitation due to its thick thickness and heavy weight.

Therefore, an electronic device which is slim but generates a large amount of heat, such as a central processing unit (CPU) of a laptop computer, is cooled by using both a compact heat pipe having a high heat diffusion rate and a relatively large heat sink having a high heat conduction rate. The heat pipe is attached to the topside of the electronic device, and heat generated from the electronic device is transferred through the heat pipe to the relatively large heat sink.

Therefore, what is needed is an inexpensive thin heat cooler that has high heat diffusion and conduction rates and can be easily used regardless of installation environments.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a heat cooler having high heat diffusion and conduction rates and configured to be easily adjusted in heat diffusion and conduction rates.

Another object of the present invention is to provide a heat cooler having high heat diffusion and conduction rates by increasing the inner surface area of a metal pipe to facilitate circulation of a refrigerant by the capillary phenomenon.

Another object of the present invention is to provide a heat cooler having high heat diffusion and conduction rates by using latent heat and specific heat of heat conductive beads.

Another object of the present invention is to provide a heat cooler having high heat diffusion and conduction rates in the scale of micrometers.

Another object of the present invention is to provide a thin heat cooler that can be easily fabricated.

Another object of the present invention is to provide an efficient heat cooler that has good cooling ability and can be easy used in various application conditions.

Another object of the present invention is to provide a heat cooler having uniform heat diffusion and conduction rates regardless of the installation position of the heat cooler.

According to an aspect of the present invention, there is provided a heat cooler including: a heat conductive body having a predetermined volume, the body including a plurality of bores formed through top and bottom surfaces of the body; and sealing members hermetically coupled to the top and bottom surfaces of the body, wherein the bores are sealed with the sealing members to form independent accommodation portions, and a plurality of heat conductive beads and a refrigerant are filled in the accommodation portions in a state where the refrigerant permeates between the heat conductive beads.

According to another aspect of the present invention, there is provided a heat cooler including: a heat conductive body having a predetermined volume, the body including a plurality of bores formed through top and bottom surfaces of the body; and sealing members hermetically coupled to the top and bottom surfaces of the body, wherein the bores are connected to each other through a gap formed between one of the sealing members and the top surface or the bottom surface of the body, a plurality of heat conductive beads and a refrigerant are filled in the bores in a state where the refrigerant permeates between the heat conductive beads, and the refrigerant is allowed to flow horizontally among the bores through the gap.

According to another aspect of the present invention, there is provided a heat cooler including: a heat conductive body having a predetermined volume, the body including a plurality of accommodation grooves formed in one of top and bottom surfaces of the body; and a sealing member hermetically coupled to the one of the top and bottom surfaces of the body, wherein a plurality of heat conductive beads and a refrigerant are filled in the accommodation grooves in a state where the refrigerant permeates between the heat conductive beads.

According to another aspect of the present invention, there is provided a heat cooler including: a sealing member attached to a heat-generating device to receive heat from the heat-generating device; and a heat conductive body hermetically coupled to a top surface of the sealing member, wherein a plurality of hollow protrusions are formed in one piece with the body and are independently sealed with the sealing member, and a plurality of heat conductive beads and a refrigerant are filled in the hollow protrusions in a state where the refrigerant permeates between the heat conductive beads.

According to another aspect of the present invention, there is provided a heat cooler including: a heat conductive body having a one-piece pipe shape and sealed with sealing members at both ends thereof; a heat conductive beads filled in the body; and a refrigerant filling gaps formed between the heat conductive beads.

According to another aspect of the present invention, there is provided a heat cooler including: a one-piece heat conductive body including a plurality of longitudinal independent penetration holes positioned close to each other; sealing members disposed on both ends of the body to seal the penetration holes; a plurality of heat conductive beads filled in the penetration holes; and a refrigerant filling gaps formed between the heat conductive beads.

BRIEF DESCRIPTION OF THE DRAWINGS

The above objects and other advantages of the present invention will become more apparent by describing in detail preferred embodiments thereof with reference to the attached drawings in which:

FIG. 1 is an exploded perspective view illustrating a heat cooler according to an embodiment of the present invention;

FIG. 2 is an assembled perspective view of FIG. 1;

FIGS. 3A and 3B are views illustrating heat coolers 110 and 120 modified from the heat cooler of FIG. 1;

FIG. 4 is a sectional view illustrating an inside of the heat cooler of FIG. 1;

FIG. 5 is a sectional view illustrating an inside of the heat cooler of FIG. 3A;

FIG. 6 is a view illustrating an application example of the heat cooler of FIG. 1;

FIG. 7 is a view illustrating another application example of the heat cooler of FIG. 1;

FIG. 8 is a sectional view illustrating a heat cooler according to another embodiment of the present invention;

FIG. 9 is a plan view illustrating the heat cooler of FIG. 8;

FIG. 10 is a perspective view illustrating a heat cooler according to another embodiment of the present invention; and

FIG. 11 is a perspective view illustrating a heat cooler according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Exemplary embodiments of the present invention will be described below in more detail with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view illustrating a heat cooler 100 according to an embodiment of the present invention, and FIG. 2 is an assembled perspective view illustrating the heat cooler 100 of FIG. 1.

The heat cooler 100 includes a body 20 and metal foils 10 and 30 attached to the top and bottom surfaces of the body 20 to seal the body 20. At least one of the top and bottom surfaces of the heat cooler 100 is a horizontal surface.

The body 20 has a one-piece sheet shape with a uniform thickness, and a plurality of separate bores 22 are formed through the top and bottom surfaces of the body 20. The body 20 is formed of one of a metal, a ceramic material, graphite, and carbon that have good heat conductivity and heat dissipation and diffusion characteristics. The body 20 has a thickness in the range from about 0.3 mm to about 20 mm.

For example, the body 20 may be formed of graphite to rapidly diffuse generated from a heat-generating device in a horizontal direction. In this case, however, the manufacturing process of the body 20 may be difficult, and the manufacturing cost of the body 20 may be increased.

The bores 22 may be formed using a press, a laser, or a mold. In this case, the bores 22 may be easily formed with low costs. The bores 22 may have the circular cross section and diameter so that the bores 22 can be easily formed with low costs. For example, the bores 22 may have a diameter of 0.3 mm to 3 mm.

In FIG. 1, the bores 22 are independently formed. However, the present invention is not limited thereto. For example, as shown in FIG. 7, a gap may be formed between the body 20 and the metal foil 10 such that a region of the body 20 where the bores 22 are formed is lower than the other region of the body 20. In this case, a refrigerant may flow horizontally between neighboring bores 22 through the gap.

In the embodiment shown in FIG. 1, since the bores 22 form independently sealed spaces, the heat conduction and diffusion rates of the heat cooler 100 may be substantially uniform regardless of the position of a device where the heat cooler 100 is attached. For example, the positions of heat conductive beads 24 and a refrigerant 25 filled in the bores 22 may be varied according to whether a device to which the heat cooler 100 is attached is erected or laid, and thus the heat diffusion and conduction rates of the heat cooler 100 may be locally varied. However, such variations may not be large because the bores 22 are independently provided.

As shown in FIG. 2, the metal foil 10 is bonded to the top surface of the body 20 using a heat conductive adhesive 40, and the metal foil 30 is bonded to the bottom surface of the body 20 using a heat conductive adhesive 42.

The heat conductive adhesives 40 and 42 may include one of heat conductive polymer adhesives, heat conductive elastic rubber adhesives, heat conductive epoxy adhesives, and heat conductive acryl adhesives. If the heat conductive adhesives 40 and 42 include a heat conductive elastic adhesive, the heat conductive adhesives 40 and 42 may be elastic and not deformed by heat after being hardened. Therefore, bonding processes may be easily carried out, and a refrigerant may be reliably sealed.

A metal cap may be used instead of the metal foil 10. In addition, soldering or welding such as metal spot welding may be used instead of using the heat conductive adhesives 40 and 42 so as to bond the metal foils 10 and 30.

If a welding method is used, heat conduction and diffusion may be improved although manufacturing cost may be increased. If a heat conductive polymer adhesive is used, although heat conduction and diffusion are decreased, bonding processes may be easily carried out, and a refrigerant may be reliably sealed in the bores 22.

The thickness of the metal foils 10 and 30 may be equal to or less than ⅓ the thickness of the body 20. For example, the thickness of the metal foils 10 and 30 may be about 0.12 mm. However, the present invention is not limited thereto. The metal foils 10 and 30 may be formed of one of copper, aluminum, magnesium and an alloy thereof.

FIGS. 3A and 3B are views illustrating heat coolers 110 and 120 modified from the heat cooler 100 of FIG. 1.

Referring to FIG. 3A, the heat cooler 110 includes a body 50 and a metal foil 30 bonded to the body 50 using a heat conductive adhesive 40. At least one groove 52 formed in the body 50 are opened only at a side facing the metal foil 30.

Therefore, the metal foil 30 is bonded to only the bottom surface of the body 50. The top surface of the body 50 may function as the metal foil 10 of FIG. 1. In this case, although it is difficult to form the groove 52, the heat diffusion rate of the heat cooler 110 can be increased. In addition, the heat conduction efficiency of the heat cooler 110 can be improved.

Referring to FIG. 3B, the heat cooler 120 has a structure opposite to that of the heat cooler 110 shown in FIG. 3A. That is, in the heat cooler 120, a metal foil 10 is bonded to the top surface of a body 50 using a heat conductive adhesive 40. A groove 52 (refer to FIG. 3A) formed in the body 50 are opened only at sides facing the metal foil 10.

FIG. 4 illustrates an inside structure of the bore 22 illustrated in FIG. 1, and FIG. 5 illustrates an inside structure of the groove 52 shown in FIG. 3A.

As shown in FIGS. 4 and 5, heat conductive beads 24 such as heat conductive powder, heat conductive particles, or heat conductive balls are placed in the bore 22, and heat conductive beads 54 such as heat conductive powder, heat conductive particles, or heat conductive balls are placed in the groove 52. A refrigerant 25 such as distilled water is partially or fully filled in the bore 22 to fill gaps between the heat conductive beads 24, and a refrigerant 55 such as distilled water is partially or fully filled in the groove 52 to fill gaps between the heat conductive beads 54.

The heat conductive beads 24 and 54 may be formed of one of a heat conductive metal, a heat conductive ceramic material, heat conductive carbon, and a combination thereof. However, materials that can be used to form the heat conductive beads 24 and 54 are not limited thereto.

The heat conductive beads 24 may occupy equal to or greater than 30% of the inside volume of the bore 22 to increase the heat diffusion and conduction rates of the heat cooler 100. The heat conductive beads 54 may occupy equal to or greater than 30% of the inside volume of the groove 52 to increase the heat diffusion and conduction rates of the heat cooler 110 (120).

The sizes of the heat conductive beads 24 and 54 may be equal. Alternatively, small beads and relatively large beads may be used together according to the kind and viscosity of a refrigerant.

If small heat conductive beads 24 and 54 are filled in the bore 22 and the groove 52, since gaps between the heat conductive beads 24 and 54 are small, heat conduction increases but heat diffusion decreased. On the contrary, if relatively larger heat conductive beads 24 and 54 are filled in the bore 22 and the groove 52, since gaps between the heat conductive beads 24 and 54 are large, heat diffusion increases but heat conduction decreases. Therefore, the kind, amount, and size of the heat conductive beads 24 and 54 may be properly selected according to desired heat diffusion and conduction rates.

The sizes of the heat conductive beads 24 may be equal to or smaller than ⅓ the diameter of the bore 22, and the sizes of the heat conductive beads 54 may be equal to or smaller than ⅓ the diameter of the groove 52. For example, the sizes of the heat conductive beads 24 and 54 may be in the range from 0.01 mm to 1 mm.

The refrigerant 25 may be one of a liquid refrigerant, a gas refrigerant, and a mixture thereof, and the refrigerant 55 may be one of a liquid refrigerant, a gas refrigerant, and a mixture thereof.

As shown in FIG. 5, the refrigerant 55 may be partially filled in the groove 52 if the refrigerant 55 is a liquid refrigerant. That is, not all the heat conductive beads 54 are submerged in the refrigerant 55.

A material having a relative low boiling point, such as distilled water and alcohol, may be used as a liquid refrigerant. However, the present invention is not limited thereto. A material having a relatively low specific gravity such as helium (He) gas may be used as a gas refrigerant. However, the present invention is not limited thereto.

Vacuum spaces 26 and 56 may be formed in the bore 22 and the groove 52 for heat diffusion at a low temperature.

That is, since the pressures of the vacuum spaces 26 and 56 are low, the refrigerants 25 and 55 may be easily evaporated even at a low temperature to facilitate heat diffusion.

The diameters and heights of the bore 22 and the groove 52 are not limited to specific values as long as the refrigerants 25 and 55 can be circulated between high-temperature regions close to heat sources and low-temperature regions opposite to the high-temperature regions. For example, if the diameters of the bore 22 and the groove 52 are excessively large as compared with the heights of the bore 22 and the groove 52, high-temperature regions and low temperature regions may not be clearly distinguished in the bore 22 and the heat conductive beads 54, and thus the refrigerants 25 and 55 may be only in a gas state.

In the current embodiment, copper beads are placed in the bore 22 and groove 52 as the heat conductive beads 24 and 54; distilled wafer is filled in the bore 22 and the groove 52 as the refrigerants 25 and 55; and the vacuum spaces 26 and 56 are formed in the bore 22 and the groove 52. However, the present invention is not limited thereto.

In the current embodiment, the heat conductive beads 24 and 54 and the refrigerants 25 and 55 are filled in the bore 22 and the groove 52. However, the present invention is not limited thereto. For example, sol or gel prepared by mixing distilled water with heat conductive beads such as copper, ceramic, or carbon beads may be filled in the bore 22 and the groove 52. In this case, processes of filling the sol or gel in the bore 22 and the groove 52 may be easily carried out while maintaining the cooling effects.

As described above, the numbers and sizes of the bores 22 and the grooves 52, the material and sizes of the heat conductive beads 24 and 54, and the kind and amount of the refrigerants 25 and 55 may be varied to adjust the heat diffusion and conduction rates of the heat coolers 100, 110, and 120 having predetermined sizes to optimal values.

FIG. 6 is a view illustrating an application example of the heat cooler 100 of FIG. 1.

The heat cooler 100 of the present invention is placed on a heat-generating device 1 such as a semiconductor chip which is mounted on a circuit board. The heat cooler 100 is placed on the heat-generating device 1 using a heat conductive adhesive 2 such as a thermal pad, a thermal tape, and a thermal paste, and a heat sink 5 is placed on the heat cooler 100 using a heat conductive adhesive 2 a.

The heat cooler 100 may extend from the heat-generating device 1, and an auxiliary heat sink 5 a may be disposed on the extending portion of the heat cooler 100, so as to dissipate heat from the heat-generating device 1 more rapidly.

In the above-described structure, heat generated from the heat-generating device 1 is transferred to the heat cooler 100 having a predetermined size. Then, the distilled water 25 filled in the bores 22 are evaporated by the heat and are moved upward through the gaps between the heat conductive beads 24 formed of, for example, copper by the capillary phenomenon. Along with this, heat is dissipated to an outside area through the body 20.

Thereafter, if the body 20 is cooled, vapor condenses back to the distilled water 25, and the condensed distilled water 25 moves rapidly down to the lower sides of the bores 22 through the gaps between the copper beads 24. Then, the distilled water 25 is evaporated again by heat from the heat-generating device 1. That is, the heat cooler 100 functions as a heat sink having high heat conductivity because heat is conducted to an outside area through the copper beads 24 and the body 20 of the heat cooler 100. In addition, the heat cooler 100 functions as a heat pipe having good heat diffusion characteristics because heat is diffused as the distilled water 25 filled in the bores 22 is rapidly circulated between the lower and upper sides of the bores 22 while being evaporated and condensed.

Some of heat generated from the heat-generating device 1 is transferred to the heat conductive beads 24 having high heat conductivity. That is, since the heat conductive beads 24 function as a heat absorber, the effective heat-transfer volume of the heat cooler 100 is increased so that heat generated from the heat-generating device 1 can be rapidly transferred to cool the heat-generating device 1.

Therefore, owing to the heat conductive beads 24 filled in the bores 22, the heat conduction rate of the heat cooler 100 can be greater than that of a related-art heat sink, and the heat diffusion rate of the heat cooler 100 can be greater than that of a related-art heat pipe.

In other words, owing to the heat conductive beads 24 filled in the bores 22, the heat diffusion and conduction rates of the heat cooler 100 can be higher than those of a related-art heat cooler having the same size.

In addition, since the vacuum spaces 26 are formed in the bores 22, the distilled water 25 filled in the bores 22 can be evaporated at a relatively low temperature owing to the vacuum conditions and evaporation spaces provided by the vacuum spaces 26. Therefore, the heat conduction and diffusion rates of the heat cooler 100 can be improved.

FIG. 7 is a view illustrating another application example of the heat cooler 100 of FIG. 1.

Referring to FIG. 1, since the bores 22 have the same height and are sealed as independent regions, the heat diffusion rate of the heat cooler 100 may be relative low in a lateral direction.

Referring to FIG. 7, the height of some of the bores 22 is adjusted so that a gap can be formed between some of the bores 22 and the metal foil 10. Therefore, a liquid or gas refrigerant can flow horizontally between neighboring bores 22 through the gap.

In this case, the heat diffusion rate of the heat cooler 100 can be increased; however, it may be difficult to make the heat cooler 100, and the heat diffusion and conduction rates of the heat cooler 100 may be varied according to the installation position of the heat cooler 100.

FIGS. 8 and 9 illustrate a heat cooler 130 according to another embodiment of the present invention.

In the current embodiment, a body 131 is bonded to a metal foil 132 using a heat conductive adhesive 134.

A plurality of hollow protrusions 136 are formed in one piece with the body 131, and heat conductive beads 137 are filled in the hollow protrusions 136. Distilled water 138 is filled between the heat conductive beads 137 as a liquid refrigerant.

The body 131 may be formed of a metal plate having a thickness in the range from 0.08 mm to 0.3 mm, and the hollow protrusions 136 may be formed through a deep drawing process. However, the present invention is not limited thereto. For example, the body 131 may be formed of metal or carbon through a molding process.

The hollow protrusions 136 may have a height in the range from 1 mm to 20 mm, and vacuum spaces 135 may be formed in the hollow protrusions 136.

In the current embodiment, heat is transferred to the body 131 through the metal foil 132. In the hollow protrusions 136 of the body 131, heat is diffused as the distilled water 138 is evaporated by the heat and is moved upward through gaps between the heat conductive beads 137. Along with this, the heat is dissipated to the outside of the hollow protrusions 136.

Both the edge of the body 131 and the edge of the metal foil 132 are coated with a metal plate layer 133 to prevent leakage of the distilled water 138 from the hollow protrusions 136. In addition, heat can be transferred from the metal foil 132 to the body 131 through the metal plate layer 133.

As compared with a related-art heat sink, the heat cooler 130 of the current embodiment is lighter and can be fabricated more easily. In addition, the heat diffusion rate of the heat cooler 130 is high.

Furthermore, since the heat cooler 130 has a large surface area owing to the hollow protrusions 136, the cooling ability of the heat cooler 130 can be improved.

In addition, since the height of the heat cooler 130 is varied owing to the hollow protrusions 136, air may swirl around the heat cooler 130 to cause convection, and thus the cooling ability of the heat cooler 130 may be improved.

FIG. 10 is a cutaway view illustrating a heat cooler 200 according to another embodiment of the present invention.

According to the current embodiment, a bore 214 is formed in a length direction of a metal pipe body 210 of the heat cooler 200. Grooves 212 are formed on an inner surface of the bore 214 in a length direction of the metal pipe body 210 and arranged in a circumferential direction of the metal pipe body 210, or a wick 240 formed of a braided wire is disposed in the bore 214. In addition, heat conductive beads 220 are filled in the bore 214 of the metal pipe body 210, and a refrigerant 230 is filled between the heat conductive beads 220, so as to improve the cooling efficiency of the heat cooler 200.

Alternatively, both the grooves 212 and the wick 240 may be provided in the metal pipe body 210. In addition, like in the above-described embodiments, vacuum spaces may be formed in the bore 214 to facilitate circulation of the refrigerant 230.

Both ends of the heat cooler 200 are sealed with metal caps 250 by using a heat conductive adhesive or through a soldering or welding process.

The heat cooler 200 has a long shape.

In the current embodiment, the heat cooler 200 includes the metal pipe body 210. However, the present invention is not limited thereto. For example, the heat cooler 200 may include a plate-shaped metal body instead of the metal pipe body 210.

FIG. 11 is a cutaway view illustrating a heat cooler 300 according to another embodiment of the present invention.

According to the current embodiment, a plurality of penetration holes 314 are formed in a length direction of a body 310, heat conductive beads 320 are filled in the penetration holes 314, and a refrigerant 330 is filled between the heat conductive beads 320.

Like in the above-described embodiments, vacuum spaces may be formed in the penetration holes 314 to facilitate circulation of the refrigerant 330.

Both ends of the heat cooler 300 are sealed with metal caps 350 by using a heat conductive adhesive or through a soldering or welding process.

As described above, according to the present invention, the heat diffusion and conduction rates of the heat cooler can be high as compared with a related-art heat sink. In addition, the heat diffusion and conduction rates of the heat cooler can be adjusted.

In addition, the internal surfaces of a metal pipe can be increased to facilitate circulation of a refrigerant by the capillary phenomenon. Therefore, the heat diffusion and conduction rates can be increased.

In addition, heat generated from a heat-generating device can be diffused and dissipated more efficiently by using the latent heat and specific heat of heat conductive beads.

In addition, both heat diffusion and conduction can be rapid on the scale of micrometers.

In addition, the heat cooler of the present invention can be easily fabricated in a small size.

In addition, the heat cooler of the present invention can be easily adapted to application environments for efficient cooling.

In addition, according to the present invention, the heat diffusion and conduction rates of the heat cooler can be substantially uniform regardless the installation of the heat cooler.

While the present invention has been described in detail, it should be understood that various changes, substitutions and alterations can be made hereto without departing from the spirit and scope of the invention as defined by the appended claims. 

1. A heat cooler comprising: a heat conductive body having a predetermined volume, the body comprising a plurality of bores formed through top and bottom surfaces of the body; and sealing members hermetically coupled to the top and bottom surfaces of the body, wherein the bores are sealed with the sealing members to form independent accommodation portions, and a plurality of heat conductive beads and a refrigerant are filled in the accommodation portions in a state where the refrigerant permeates between the heat conductive beads.
 2. The heat cooler of claim 1, wherein the body is formed of one of a metal, graphite, and carbon.
 3. The heat cooler of claim 1, wherein vacuum spaces are formed in portions of the accommodation portions where the heat conductive beads are not filled.
 4. The heat cooler of claim 1, wherein grooves are formed in inner surfaces of the accommodation portions in a height direction of the body, or wicks are disposed in the accommodation portions.
 5. The heat cooler of claim 1, wherein the accommodation portions have a sufficient height such that high-temperature regions and low-temperature regions are formed in the accommodation portions when heat is transferred to the heat cooler so as to cause the refrigerant to circulate in the accommodation portions while the refrigerant evaporates.
 6. The heat cooler of claim 1, wherein the heat conductive beads are formed of one of a metal, a ceramic material, a carbon material, and a combination thereof.
 7. The heat cooler of claim 1, wherein the heat conductive beads have a size equal to or smaller than ⅓ the diameter of cross sections of the accommodation portions.
 8. The heat cooler of claim 1, wherein the heat cooler has a plate shape, and a width and a length of the heat cooler are greater than a thickness of the heat cooler.
 9. The heat cooler of claim 1, wherein at least one of top and bottom surfaces of the heat cooler is horizontal surface.
 10. The heat cooler of claim 1, wherein the sealing members are metal foils or metal caps.
 11. The heat cooler of claim 10, wherein the sealing members are coupled to the top and bottom surfaces of the body by using one of a heat conductive elastic rubber adhesive, a heat conductive epoxy adhesive, a heat conductive acryl adhesive, a soldering process, and a metal-welding process.
 12. The heat cooler of claim 1, wherein the heat conductive beads filled in the accommodation portions occupy 30% or more of inner volumes of the accommodation portions.
 13. A heat cooler comprising: a heat conductive body having a predetermined volume, the body comprising a plurality of bores formed through top and bottom surfaces of the body; and sealing members hermetically coupled to the top and bottom surfaces of the body, wherein the bores are connected to each other through a gap formed between one of the sealing members and the top surface or the bottom surface of the body, a plurality of heat conductive beads and a refrigerant are filled in the bores in a state where the refrigerant permeates between the heat conductive beads, and the refrigerant is allowed to flow horizontally among the bores through the gap.
 14. A heat cooler comprising: a heat conductive body having a predetermined volume, the body comprising a plurality of accommodation grooves formed in one of top and bottom surfaces of the body; and a sealing member hermetically coupled to the one of the top and bottom surfaces of the body, wherein a plurality of heat conductive beads and a refrigerant are filled in the accommodation grooves in a state where the refrigerant permeates between the heat conductive beads.
 15. A heat cooler comprising: a sealing member attached to a heat-generating device to receive heat from the heat-generating device; and a heat conductive body hermetically coupled to a top surface of the sealing member, wherein a plurality of hollow protrusions are formed in one piece with the body and are independently sealed with the sealing member, and a plurality of heat conductive beads and a refrigerant are filled in the hollow protrusions in a state where the refrigerant permeates between the heat conductive beads.
 16. The heat cooler of claim 15, wherein vacuum spaces are formed in portions of the hollow protrusions where the heat conductive beads are not filled.
 17. A heat cooler comprising: a heat conductive body having a one-piece pipe shape and sealed with sealing members at both ends thereof; a heat conductive beads filled in the body; and a refrigerant filling gaps formed between the heat conductive beads.
 18. The heat cooler of claim 17, wherein a groove is formed on an inner surface of the body in a length direction of the body, or a wick is disposed in the body.
 19. A heat cooler comprising: a one-piece heat conductive body comprising a plurality of longitudinal independent penetration holes positioned close to each other; sealing members disposed on both ends of the body to seal the penetration holes; a plurality of heat conductive beads filled in the penetration holes; and a refrigerant filling gaps formed between the heat conductive beads. 